Summary
Plant meristems integrate signals from water conditions to tune their proliferative activity and control growth. While extensive progress has been made elucidating water stress responses in plants, how cells in aerial meristems sense hydraulic fluctuations remains largely unknown. The vascular cambium (VC), the largest plant meristem, contributes to the radial growth of shoots and roots by producing xylem and phloem tissue. Theoretical models for cambial growth predict that water-dependent turgor pressure stimulates (locally) the proliferative activity in this meristem. These models are extensively supported by correlative studies in greenhouse and field conditions, yet how turgor pressure is sensed and transduced into a cell proliferation response is still unknown. This is what I would like to investigate during my postdoc at the Mähönen group. To do so, I will be trained in the design and implementation of the latest lineage tracing and genome editing tools from the hosting lab. I will contribute with my background in meristem hydraulics to reveal the dynamics of cambial cells under water deficit. Since the VC is directly connected with water-transporting cells, hydraulic fluctuations can have a direct physical effect in cambial cells, more specifically at the plasma membrane where key osmosensors are localized. Therefore, I will study the function of osmosensing channels in the context of cambial developmental plasticity. Finally, I will identify regulators of cambial activity dependent on water status. This project aims at 1) Generating a growth rate and cell fate map for the cambium under variations of water status, 2) Identifying osmosensing channels involved in the control of cambial activity, and 3) Uncovering cambial molecular factors transcriptionally sensitive to water status. Taken together, this project will provide me with a material and conceptual platform for developing a career studying the hydraulic control of plant growth.
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| Web resources: | https://cordis.europa.eu/project/id/101150831 |
| Start date: | 01-05-2024 |
| End date: | 30-04-2026 |
| Total budget - Public funding: | - 199 694,00 Euro |
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Original description
Plant meristems integrate signals from water conditions to tune their proliferative activity and control growth. While extensive progress has been made elucidating water stress responses in plants, how cells in aerial meristems sense hydraulic fluctuations remains largely unknown. The vascular cambium (VC), the largest plant meristem, contributes to the radial growth of shoots and roots by producing xylem and phloem tissue. Theoretical models for cambial growth predict that water-dependent turgor pressure stimulates (locally) the proliferative activity in this meristem. These models are extensively supported by correlative studies in greenhouse and field conditions, yet how turgor pressure is sensed and transduced into a cell proliferation response is still unknown. This is what I would like to investigate during my postdoc at the Mähönen group. To do so, I will be trained in the design and implementation of the latest lineage tracing and genome editing tools from the hosting lab. I will contribute with my background in meristem hydraulics to reveal the dynamics of cambial cells under water deficit. Since the VC is directly connected with water-transporting cells, hydraulic fluctuations can have a direct physical effect in cambial cells, more specifically at the plasma membrane where key osmosensors are localized. Therefore, I will study the function of osmosensing channels in the context of cambial developmental plasticity. Finally, I will identify regulators of cambial activity dependent on water status. This project aims at 1) Generating a growth rate and cell fate map for the cambium under variations of water status, 2) Identifying osmosensing channels involved in the control of cambial activity, and 3) Uncovering cambial molecular factors transcriptionally sensitive to water status. Taken together, this project will provide me with a material and conceptual platform for developing a career studying the hydraulic control of plant growth.Status
SIGNEDCall topic
HORIZON-MSCA-2023-PF-01-01Update Date
12-03-2024
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